INTERFERENCE-RESISTANT WIRELESS AUDIO SYSTEM AND THE METHOD THEREOF

Abstract

An interference-resistant method for a wireless audio system capable of transforming an audio signal into an RF signal includes transforming the audio signal into a PCM signal, appending a first control signal to the PCM signal, and modulating the PCM signal with the first control signal into an analog base-band signal. The method further includes up-converting the analog base-band signal into the RF signal and transmitting the RF signal into the air in a transmitting mode and receiving the RF signal in the air during a receiving mode. The channel is switched to another one upon determining that a Received Signal Strength Indicator (RSSI) level of the RF signal is greater than a first predetermined value a plurality of times within a predetermined time interval.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of applicant's earlier application, Ser. No. 10/907,380, filed Mar. 31, 2005, the entirety of which is incorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a wireless audio system, and more particularly, to an interference-resistant wireless audio system and related method.

2. Description of the Prior Art

In recent years, due to the progressive development of wireless communications technology, a variety of electronic device comprising a wireless communication module can wirelessly transmit and receive audio signals and data signals.

Please refer to FIG. 1, which is a functional block diagram of a wireless audio system 10 according to the prior art. The wireless audio system 10 comprises a transmitter 12 for transforming an analog audio signal into an RF signal and for transmitting the RF signal into the air, and a receiver 14 for receiving the RF signal in the air and for transforming the received RF signal into a corresponding analog audio signal. Therefore, a user can hear the analog audio signal from the receiver 14.

The transmitter 12 comprises an audio signal receiver 16, an audio data format converter 18, a frame & coding unit 20, a modulation module 22, and an RF transmitter 24.

The audio signal receiver 16, along with the audio data format converter 18, sample the analog audio signals and a plurality of digitized sampling data points are acquired, each of which corresponds to an amplitude and phase of the analog audio signal at a predetermined sampling rate. Then the sampling data points are transformed into a digital signal P₁ formatted for the pulse-code modulation (PCM). Thereafter, the frame & coding unit 20 appends a header and a tail serving as an error protection code to the digital signal P₁, and generates a bit-streamed frame signal P₂, which will be transmitted to the modulation module 22 bit by bit. The modulation module 22 modulates the bit-streamed frame signal P₂ into an analog base-band signal P₃ suit for wireless communications. Subsequently, the RF transmitter 24 up-converts the analog base-band signal P₃ into an RF signal P₄, and wirelessly transmits the RF signal P₄ into the air.

The receiver 14 comprises an RF receiver 26, a demodulation module 28, a frame synchronization controller 30, a digital-to analog converter (DAC) 32, and a detachable speaker 34.

After receiving the RF signal P₄ transmitted by the transmitter 12, the RF receiver 26 down-converts the RF signal P₄ into a base-band signal P₅, which corresponds to the base-band signal P₃. The demodulation module 28 then demodulates the base-band signal P₅ into a bit-streamed frame signal P₆ corresponding to the frame signal P2 which is suit for digitally serial transmission. The frame synchronization controller 30 parses the header and the tail appended to the frame signal P₆, and identifies the correctness to acquire a digital audio signal P₇. After the DAC 32 transforms the digital audio signal P₇ into an analog audio signal, the speaker 34 plays the analog audio signal transformed by the DAC 32.

Ideally, the analog audio signal played by the speaker 34 should be the same as that inputted into the audio signal receiver 16. Besides, all wireless communication devices usually use the unlicensed band, such as 2.4 G ISM band or 5 G ISM band, which are defined by the wireless legislation of Governments. For example, FCC in US or CE in Europe.

Please refer to FIG. 7 and FIG. 2 FIG. 7 lists a plurality of channels and their corresponding channel center frequencies in WLAN 802.11b and 802.11g standard. FIG. 2 is a frequency spectrum of the channels in WLAN 802.11b and 802.11g standard. As FIG. 2 shows, each of the channels occupies a bandwidth as wide as 22 MHz, while the difference between any two neighboring channel is as narrow as 5 MHz only. Thus, two RF signals respectively transmitted by the wireless communication devices will interfere with each other if the interval of the channels are not wider than four channels.

When a channel used by a wireless communication device is overlapped by another one, the RF signals transmitted by the wireless communication device are interfered. Therefore, the severely distorted analog audio signals are generated, and the speaker 34 will mute in order not to output unendurable noises. Sometimes, the interference problem is so severe that a wireless communications link between the transmitter 12 and the receiver 14 is severely impacted or even failed.

When the distortion, the noises, or the fail of the wireless communication link resulted from the interference problem occur, the wireless audio system 10 executes the mute process to control the speaker 34 not to play the probably contaminated analog audio signal until the interference problem is gone. However, if the speaker 34 is playing music, the mute process will interrupt the music and spoils the mood of a user to enjoy the music.

In addition to the mute process, the wireless audio system 10 can get rid of the interference problem by switching the interfered channel manually. However, the switching process is inconvenienced for the user because he has to switch the channel manually as hearing the noise.

SUMMARY OF THE INVENTION

It is therefore an objective of the claimed invention to provide an interference-resistant wireless audio system and the method thereof, which has a capability to detect any errors resulted from the interference, and to switch the used channel to another one to output audio signals as clear as possible.

In order to accomplish the objective, the present invention provides an interference-resistant method for a wireless audio system capable of transforming an audio signal into an RF signal. The method includes transforming the audio signal into a PCM signal, appending a first control signal to the PCM signal, and modulating the PCM signal with the first control signal into an analog base-band signal. The method further includes up-converting the analog base-band signal into the RF signal and transmitting the RF signal into the air in a transmitting mode and receiving the RF signal in the air during a receiving mode. The channel is switched to another one upon determining that a Received Signal Strength Indicator (RSSI) level of the RF signal is greater than a first predetermined value a plurality of times within a predetermined time interval.

In order to accomplish the objective, the present invention also provides an interference-resistant method for a wireless audio system capable of transforming an audio signal into an RF signal. The method includes transforming the audio signal into a PCM signal, appending a first control signal to the PCM signal, and modulating the PCM signal with the first control signal into an analog base-band signal. The method further includes up-converting the analog base-band signal into the RF signal and transmitting the RF signal into the air in a transmitting mode and receiving the RF signal in the air during a receiving mode. The channel is switched to another one upon determining that a correlation value of the RF signal with a barker code is greater than a first predetermined value a plurality of times within a predetermined time interval.

These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a functional block diagram of a wireless audio system according to the prior art.

FIG. 2 is a frequency spectrum of a plurality of channels in WLAN 802.11b and 802.11g standard.

FIG. 3 is a functional block diagram of a wireless audio system of a first embodiment according to the present invention.

FIG. 4 is an interference-resistant method corresponding to the wireless audio system shown in FIG. 3.

FIG. 5 is a functional block diagram of a wireless audio system of a second embodiment according to the present invention.

FIG. 6 is an interference-resistant method corresponding to the wireless audio system shown in FIG. 5.

FIG. 7 lists a plurality of channels and their corresponding channel center frequencies in WLAN 802.11b and 802.11g standard.

FIGS. 8 and 9 contain a flow chart of an interference detection method according to a third embodiment of the present invention.

DETAILED DESCRIPTION

Please refer to FIG. 3, which is a functional block diagram of a wireless audio system 50 of a first embodiment according to the present invention. The wireless audio system 50 comprises a transmitter 52 and a receiver 54.

Besides receiving the RF signals transmitted by the transmitter 52, the receiver 54 further transmits a control signal Pc into the air if the bit errors being detected exceed a predetermined number in a period of time. After receiving the control signal Pc, the transmitter 52 switches the used channel to another one. Thus, the user doesn't have to suffer unendurable noises and switch the channel manually because the transmitter 52 has accomplished automatically.

In addition to the RF receiver 26, the demodulation module 28, the frame synchronization controller 30, the DAC 32, and the detachable speaker 34, the receiver 54 further comprises a control signal transmitter 60, and an error detection controller 62 electrically connected between the demodulation module 28, the frame synchronization controller 30, and the control signal transmitter 60. The control signal transmitter 60 is controlled by the error detection controller 62 to transmit the control signal P_c into the air.

The error detection controller 62 is installed to detect errors of the frame signal P₆ outputted from the demodulation module 28, and determine if the bit error rate of the frame signal P₆ is acceptable through an error-check process by comparing the number of errors of the frame signal P₆ (including the header and the tail) with a predetermined bit error number during a unit of time T_unit. If the number of bit errors or frame errors are smaller than the predetermined bit error number during the unit of time T_unit, the error detection controller 62 determines that the bit error rate of the frame signal P₆ is acceptable, and then transmits the frame signal P₆ to the frame synchronization controller 30. On the contrary, if the number of the bit errors or frame errors are larger than the predetermined bit error number during the unit of time T_unit, the error detection controller 62 determines that the bit error rate of the frame signal P₆ is unacceptable, and therefore controls the control signal transmitter 60 to transmit the control signal P_c for switching the channel into the air.

According to the first embodiment of the present invention, the error detection controller 62 can be embodied by a microprocessor. The microprocessor can be refreshed in the end of every unit of time T_unit to recount the number of bit errors of the frame signal P₆.

On the other hand, in addition to the audio signal receiver 16, the audio data format converter 18, the frame & coding unit 20, the modulation module 22, and the RF transmitter 24, the transmitter 52 further comprises a control signal receiver 56, and a channel switch controller 58 electrically connected between the control signal receiver 56 and the RF transmitter 24. The channel switch controller 58 controls the RF transmitter 24 to switch the used channel to another one if the control signal P_c transmitted by the receiver 54 is received by the control signal receiver 56.

Further, after receiving the control signal P_c transmitted by the receiver 54, the control signal receiver 56 generates a switch signal P_s, and the channel switch controller 58 controls the RF transmitter 24 to switch the used channel to another one that is used for re-transmitting the RF signal P4. As long as the control signal receiver 56 does not receive the control signal P_c transmitted by the receiver 54, the RF transmitter 24 keeps transmitting the RF signal in the same channel that is used previously.

Please refer to FIG. 4, which is a flow chart of an interference-resistant method 100 corresponding to the first embodiment of the present invention. The method 100 comprises the following steps:

Step 102: Transforming an audio signal into a PCM signal P₁;

(Step 102 is performed by the audio signal receiver 16 and the audio data format converter 18.)

Step 104: Appending a first control signal and an encoding signal (such as a cyclic redundancy check (CRC)) to the PCM signal P₁ to form a frame signal P₂;

(Step 104 is performed by the frame & coding unit 20. Besides, in step 104 a header and a tail are appended to the PCM signal P₁.)

Step 106: Modulating the frame signal P₂ into an analog base-band signal P₃;

(Step 106 is performed by the modulation module 22.)

Step 108: Up-converting the analog base-band signal P₃ into an RF signal P₄;

(Step 108 is performed by the RF transmitter 24.)

Step 110: Transmitting the RF signal P₄ into the air;

(Step 110 is performed by an antenna of the transmitter 52. Steps 102 through 110 are those of the method 100 that are performed in the transmitter 52.)

Step 112: Receiving the RF signal P₄, and down-converting the RF signal P₄ into a base-band signal P₅;

(Step 112 is performed by an antenna of the receiver 54 and the RF receiver 26. The following steps (including Step 112) are those of the method 100 that are performed in the receiver 54.)

Step 114: Demodulating the base-band signal P₅ into a frame signal P₆, and separating the frame signal P6 into a PCM signal P₇ and a second control signal;

(Step 114 is performed by the demodulation module 28. However, the second control signal is not necessarily the same as the first control signal.)

Step 116: Determining if the bit error rate of the frame signal P₆ is acceptable? If yes, go to Step 118, else go to Step 120;

(Step 116 is performed by the error detection controller 62.)

Step 118: Transforming the frame signal P₆ into an analog audio signal;

(Step 118 is performed by the frame synchronization controller 30 and the DAC 32. The execution of the step 118 indicates that the RF signal P₄ received in Step 112 is correct.)

Step 120: Transmitting the control signal P_c into the air; and

(Step 120 is performed by the control signal transmitter 60. The execution of the step 120 indicates that the RF signal P₄ received in Step 112 is wrong.)

Step 122: Receiving the control signal P_c and switching the used channel to another one, and go to Step 110.

(Step 122 is performed by the control signal receiver 56 and the channel switch controller 58. The execution of the step 122 indicates that the RF signal P₄ received in step 112 is wrong.)

In the first embodiment of the present invention, the channel that is used by the RF transmitter 24 to transmit the RF signal P4 is different from that used by the control signal transmitter 60. For example, the transmitter 52 selects a channel of 2.4 GHz, which is one of the channels shown in FIG. 7, while the control signal transmitter 60 selects another channel of 433 MHz, so as to diminish the interference problem.

Furthermore, in the first embodiment, the transmitter 52 has to function in accordance with the receiver 54, and the receiver 54 therefore can receive non-interfered RF signal. In practice, the transmitter 52 will not actively control the RF transmitter 24 to switch the used channel to another one without receiving the control signal Pc.

Furthermore, in the first embodiment, the digital audio signal P₇ generated by the frame synchronization controller 30 is then transformed into the analog audio signal by a digital-to analog process performed by the DAC 32 so that the speaker 34 can output the analog audio signals. However, the DAC 32 of the first embodiment can be omitted, and the speaker 34 can be replaced with a digital audio speaker, which plays digital audio signals.

Please refer to FIG. 5, which is a functional block diagram of a wireless audio system 150 of a second embodiment according to the present invention. The wireless audio system 150 comprises a transceiver 152, and the receiver 14. In addition to the audio signal receiver 16, the audio data format converter 18, the frame & coding unit 20, the modulation module 22, and the channel switch controller 58, the transceiver 152 further comprises a receiving/transmitting switch controller 158 electrically connected to the modulation module 22, an RF transceiver 154 electrically connected between the receiving/transmitting switch controller 158 and the channel switch controller 58, and an RF signal detector 156 electrically connected between the RF transceiver 154 and the channel switch controller 58. Wherein the transceiver 152 can transmit and receive the RF signals in the air and detect the frequency of the channel used by the transceiver 152. Besides, the used channel will be switched to another one as long as the transceiver 152 detects another RF signal, the channel of which overlaps that being used previously.

The control of receiving/transmitting mode of the RF transceiver 154 is controlled by the receiving/transmitting switch controller 158. For example, when the receiving/transmitting switch controller 158 controls the RF transceiver 154 to operate in the transmitting mode, the base-band signal P₃ modulated by the modulation module 22 can be transferred through the receiving/transmitting switch controller 158 to the RF transceiver 154, and the RF transceiver 154 accordingly up-converts the base-band signal P₃ into the RF signal P₄ and wirelessly transmits the RF signal P₄ into the air. On the contrary, when the receiving/transmitting switch controller 158 controls the RF transceiver 154 to operate in the receiving mode, the base-band signal P₃ generated by the modulation module 22 cannot arrive the RF transceiver 154, and the RF transceiver 154 can receive nothing but the RF signals in the air accordingly.

More specifically speaking, the RF transceiver 154 is operated in the receiving mode, the RF signal detector 156 will generate a switch signal Ps when the RF transceiver 154 receives a RF signal, the power of which is strong enough to interfere the RF signal transmitted by the RF transceiver 154 previously. Similarly, after receiving the switch signal P_s, the channel switch controller 58 controls the RF transceiver 154 to switch the used channel to another one and then transmit the RF signal P₄ into the air.

Note that in the second embodiment of the present invention, the transmission data rate of the transceiver 152 is higher than that for transmitting the audio signal transmitted by the transceiver 152. For example, if the data rate of a CD or DVD player is 1.5-2 Mbps (Mega bit per sec.), the data rate of the transceiver 152 is higher than 2 Mbps, for example 5 Mbps. Thus, when the receiving/transmitting switch controller 158 is operated in the receiving mode, the working time is sufficient enough for the channel switch controller 58 to detect the RF signal received by the RF transceiver 154 and generate the switch signal Ps when the RF transceiver 154 receives a RF signal, the power of which is strong enough to interfere that of the RF signal transmitted by the RF transceiver 154.

Moreover, the RF signal detector 156 determines if two channels are overlapped by detecting whether the average power of the RF signal received by the RF transceiver 154 is stronger than a predetermined power. If yes, it is implied that the channel that the transceiver 154 used to transmit the RF signal P4 is overlapped by that used by another electronic device emits. Therefore, in order to diminish the inference problem, the channel switch controller 58 controls the RF transceiver 154 to switch the used channel to another one after receiving the switch signal P_s generated by the RF signal detector 156.

Further, similar to the wireless audio system 50 of the first embodiment, the DAC 32 of the receiver 14 can be omitted, and the speaker 34 can be replaced with a speaker capable of playing digital audio signals.

Please refer to FIG. 6, which is a flow chart of an interference-resistant method 200 corresponding to the second embodiment of the present invention. The method 200 comprises the following steps:

Step 202: Transforming an audio signal into a PCM signal P₁;

Step 204: Appending a first control signal and an encoding signal (such as CRC) to the PCM signal P₁ to form a frame signal P₂;

Step 206: Modulating the frame signal P₂ into an analog base-band signal P₃;

Step 208: Up-converting the analog base-band signal P₃ into an RF signal P₄ during a transmitting mode;

(Step 208 is performed by the RF transceiver 154.)

Step 210: Transmitting the RF signal P₄ into the air;

Step 212: Receiving the RF signal in the air during a receiving mode;

(Step 212 is performed by the receiving/transmitting switch controller 158 and the RF transceiver 154.)

Step 214: Determining if the channel of the RF signal received in step 212 overlaps that of the RF signal P₄ transmitted in step 208? If yes, go to Step 216, else go to Step 202; and

(Step 214 is performed by the RF signal detector 156.)

Step 216: Switching the channel used in step 210 to another one, and go to step 210.

In the first embodiment of the present invention, the control signal receiver 56 will transmit a control signal Pc into the air when the bit errors detected by the error detection controller 62 exceed a predetermined numbers in a period of time. After receiving the control signal P_c, the transmitter 52 switches the channel to another one. Therefore, the user doesn't have to suffer unendurable noises and switch the channel manually because the transmitter 52 accomplishes automatically. In the second embodiment of the present invention, the transceiver 152 can transmit and receive the RF signals in the air and detect the frequency of the channel used by the transceiver 152. Besides, the used channel will be switched to another one as long as the transceiver 152 detects another RF signal, the channel of which overlaps that being used previously. Thus, the interference problem can be diminished.

Please refer to FIG. 8 and FIG. 9, which contain a flow chart of an interference detection method according to a third embodiment of the present invention. The method comprises a way for detecting two kinds of interference. A first kind of interference is a continuous system, such as microwave devices, an AV sender, or a wireless LAN access point (WLAN AP). The second kind of interference is a frequency hopping spread spectrum (FHSS) system, such as a cordless phone or a Bluetooth device. The WLAN AP has two statuses: 1. beacon frame period; and 2. data transmission between the access point and a client, where the client can be a desktop PC or a notebook computer.

The RF channel can definitely be switched to the next channel when the interference type is a continuous system. However, when the interference is a FHSS system, a problem would occur where the wireless audio system would keep switching the RF channel because the FHSS interference is frequency hopping. Thus, it is necessary to recognize the FHSS interference and to not switch its RF channel automatically. To accomplish this, two methods for distinguishing between the continuous system interference and the FHSS system interference are proposed. The first method (M1) performs a Received Signal Strength Indicator (RSSI) judgment and is referred to in FIG. 9 as M1. The second method (M2) performs a correlation check and is referred to in FIG. 9 as M2.

Steps contained in the flowchart of FIG. 8 and FIG. 9 will be briefly described below with a more thorough explanation below. FIG. 8 contains steps 290-300, whereas FIG. 9 is a continuation of FIG. 8 and contains steps 302-330. The letter “A” at the end of step 300 and at the beginning of steps 302 and 318 indicates that steps 302 and 318 follow step 300. Of note, steps 290-300 shown in FIG. 8 are substantial duplicates of steps 202-212 shown in FIG. 6. Method M1 for performing RSSI judgment is shown in steps 302-316 and method M2 for performing the correlation check is shown in steps 318-330.

Step 290: Transforming an audio signal into a PCM signal P₁;

Step 292: Appending a first control signal and an encoding signal (such as CRC) to the PCM signal P₁ to form a frame signal P₂;

Step 294: Modulating the frame signal P₂ into an analog base-band signal P₃;

Step 296: Up-converting the analog base-band signal P₃ into an RF signal P₄ during a transmitting mode;

Step 298: Transmitting the RF signal P₄ into the air;

Step 300: Receiving the RF signal in the air during a receiving mode;

Step 302: Have the criteria of method M1 been met? If so, go to step 304. If not, go to step 318.

Step 304: Check the value of a counter. Is the value of the counter equal to 0? If so, go to step 306. If not, go to step 312.

Step 306: Set the counter to have a value of 1.

Step 308: Disable the processing of method M2.

Step 310: Start a timer. Go back to step 302.

Step 312: Determine if the timer has expired. If so, go to step 316. If not, go to step 314.

Step 314: Since the criteria of method M1 were met twice within the duration of the timer, switch to the next channel.

Step 316: Reset the counter back to a value of 0. Go to step 302.

Step 318: Have the criteria of method M2 been met? If so, go to step 320. If not, go to step 302.

Step 320: Check the value of the counter. Is the value of the counter equal to 0 If so, go to step 322. If not, go to step 326.

Step 322: If not, go to step 326.

Check the value of the counter. Is the value of the counter equal to 0? If so, go to step 322. If not, go to step 326.

Set the counter to have a value of 1.

Step 324: Start the timer. Go back to step 318.

Step 326: Determine if the timer has expired. If so, go to step 330. If not, go to step 328.

Step 328: Since the criteria of method M2 were met twice within the duration of the timer, switch to the next channel.

Step 330: Reset the counter back to a value of 0. Go to step 318.

Initially, the steps 302 and 318 can be executed simultaneously. Step 302 describes meeting the criteria of method M1. In order to meet the criteria of method M1, the RSSI level needs to be over a predetermined power value Pth1 for a certain number of times during a time period t1. As an example, suppose that the predetermined power value Pth1 is −50 dBm and the time period t1 is 10 ms. If the RSSI level is over the predetermined power value Pth1 for six sample measurements during the time period t1, then the criteria of method M1 are met.

Similarly, in step 318, a determination is made as to whether the criteria of method M2 are met. In order to meet the criteria of method M2, the input RF signals need to correlate with a barker code. The correlation of the input RF signals and the barker code needs to be over a predetermined value Pth2 for a certain number of times during a time period t2. As an example, suppose that the predetermined power value Pth2 is equal to two-thirds of the barker code inner product and the time period t2 is 100 μs. If the correlation target is over the predetermined value Pth2 three times during the time period t2, then the criteria of method M2 are met.

As shown in step 308 of FIG. 1, the method M1 can disable method M2 while it is processing. However, the method M2 cannot disable method M1. This means that the priority of method M1 is higher than the priority of method M2. That is, if methods M1 and M2 are both processing and the criteria of method M1 are met, method M2 stops processing immediately.

In summary, the use of the two methods M1 and M2 allows the type of interference to be distinguished as a continuous system or a FHSS system for judging whether to switch the RF channel or not.

Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.

Claims

1. An interference-resistant method for a wireless audio system capable of transforming an audio signal into an RF signal, comprising:

transforming the audio signal into a PCM signal;

appending a first control signal to the PCM signal;

modulating the PCM signal with the first control signal into an analog base-band signal;

up-converting the analog base-band signal into the RF signal and transmitting the RF signal into the air in a transmitting mode;

receiving the RF signal in the air during a receiving mode; and

switching the channel to another one upon determining that a Received Signal Strength Indicator (RSSI) level of the RF signal is greater than a first predetermined value a plurality of times within a predetermined time interval.

2. The method of claim 1, wherein determining that the RSSI level of the RF signal is greater than the first predetermined value comprises measuring a first predetermined number of samples in which the RSSI level of the RF signal is greater than the first predetermined value within a first time period.

3. The method of claim 2, wherein the predetermined value is −50 dBm, the first predetermined number is six, and the first time period is 10 ms.

4. The method of claim 1, further comprising switching the channel to another one upon determining that a correlation value of the RF signal with a barker code is greater than a second predetermined value a plurality of times within a predetermined time interval.

5. The method of claim 4, wherein determining that the correlation value of the RF signal is greater than the second predetermined value comprises measuring a second predetermined number of correlation values of the RF signal to be greater than the second predetermined value within a second time period.

6. The method of claim 5, wherein the second predetermined number is three and the second time period is 100 μs.

7. The method of claim 4, further comprising stopping determining the correlation value of the RF signal with a barker code upon determining that the RSSI level of the RF signal is greater than the first predetermined value a plurality of times within the predetermined time interval.

8. An interference-resistant method for a wireless audio system capable of transforming an audio signal into an RF signal, comprising:

transforming the audio signal into a PCM signal;

appending a first control signal to the PCM signal;

modulating the PCM signal with the first control signal into an analog base-band signal;

up-converting the analog base-band signal into the RF signal and transmitting the RF signal into the air in a transmitting mode;

receiving the RF signal in the air during a receiving mode; and

switching the channel to another one upon determining that a correlation value of the RF signal with a barker code is greater than a first predetermined value a plurality of times within a predetermined time interval.

9. The method of claim 8, wherein determining that the correlation value of the RF signal is greater than the first predetermined value comprises measuring a first predetermined number of correlation values of the RF signal to be greater than the first predetermined value within a first time period.

10. The method of claim 9, wherein the predetermined value is two-thirds of the barker code inner product, the first predetermined number is three, and the first time period is 100 μs.

11. The method of claim 8, further comprising switching the channel to another one upon determining that a Received Signal Strength Indicator (RSSI) level of the RF signal is greater than a second predetermined value a plurality of times within a predetermined time interval.

12. The method of claim 11, wherein determining that the RSSI level of the RF signal is greater than the second predetermined value comprises measuring a second predetermined number of samples in which the RSSI level of the RF signal is greater than the second predetermined value within a second time period.

13. The method of claim 12, wherein the second predetermined number is six and the second time period is 10 ms.

14. The method of claim 11, further comprising stopping determining the correlation value of the RF signal with a barker code upon determining that the RSSI level of the RF signal is greater than the second predetermined value a plurality of times within the predetermined time interval.